WO2009080940A1 - Curved disc for modifying a power of an optical component - Google Patents

Abstract

Disc designed to be attached to a concave curved surface of an optical component to modify an optical power of said component, the disc comprising a Fresnel lens made up of a series of Fresnel regions of spherical general shape, in which the changes of height between successive Fresnel regions are located on a concave face of the disc, and in which said Fresnel regions are made out in a special distribution. A disc of this kind maintains the dioptric quality without introducing distortions.

Description

 PASTILLE CURVE MODIFYING A POWER OF A

OPTICAL COMPONENT

The present invention relates to a curved patch for attachment to a concave face of an optical component for modifying an optical power thereof. It also relates to an optical element and a pair of glasses that incorporate such a patch.

It may be useful to adapt the power of an optical component according to a particular use thereof. This may be the case, for example, to adapt a glass of sun protection glasses to the ametropia of a carrier of this glass. In the context of the invention, the power of an optical component refers to the vergence of this element, and is commonly expressed in diopters.

It is known to make a pellet of transparent material which is intended to be applied on one side of an optical component, to modify the power of the latter. The pellet includes a Fresnel lens which is formed of a series of Fresnel zones disposed one inside the other parallel to a smooth face of the pellet. These zones have jumps in height between two successive zones which are greater than five times an average wavelength of visible light, the jumps in height being measured in a direction perpendicular to the tangent of its smooth face. Under these conditions, the pellet itself has an optical power which results from the refraction of the light rays on both sides of the pellet in each Fresnel zone. This optical power of the chip is added to that of the optical component to which it is applied. The use of a Fresnel lens shape reduces the thickness of the pad to achieve a fixed power change, compared to an additional lens that would be contiguous to the optical component.

These pellets have an initial planar shape, and must be curved when applied to the curved surface of a lens or an ophthalmic lens. Such pellets are described in particular in US Patent 3,904,281. This deformation of the pellet at the time of its application to the lens or to the ophthalmic lens creates distortions of an image formed through the lens or the glass, once the latter or lens is provided with the pellet, as well as optical aberrations. In particular, the distortions of the image vary dynamically when the observed object moves in the field of view or when the wearer of the glass turns his head following the object of the gaze. These image distortions are very troublesome. In addition, defects related either to diffusion and / or diffraction may appear in different areas of the pellet reinforcing the carrier gene and / or interfering with the cosmetic quality of the object, the latter being in particular identifiable by an observer placed in front of the wearer. These defects are all the more important that the change in optical power provided by the chip is high. Finally it has been found that the passage of a power modification pad from a flat surface to a curved surface causes a dioptric defect. Thus, the initial power of the tablet in planar form and the effective power of the tablet when applied to an optical component vary. This variation is highly detrimental to the quality of vision provided to a wearer. An object of the present invention is to propose an optical power modification patch which does not have the drawbacks mentioned above, and which is easy to use. Thus, the object of the present invention is to allow easy use by a simply and effortlessly wishing carrier, adapted the power of an ophthalmic lens type optical component to its personal visual correction, by simply applying the power modification patch to any optical equipment.

A solution to this technical problem consists in producing a Fresnel structure within a pellet having a spherical surface, said spherical surface being substantially identical to the spherical surface of the optical component intended to receive said pellet. In such a configuration, the object of the invention makes it possible to solve the problems of distortions, observed in the elements of the state of the art, during the passage from a flat surface to a curved surface. This is one of the features of the invention.

To better adapt the power modification chip, it is necessary to take into account the curvature of the optical component intended to receive said chip, during the design of the profile of the Fresnel structure of the chip. However, such a power modification device may have optical defects due firstly to the diffraction and secondly to the diffusion according to the considered zones of said pellet. These various problems find a global solution within the object of the present invention. Thus, the present invention comprises a Fresnel zone power modification chip having a generally spherical shape in which the distribution profile of the Fresnel zones across their amplitude and their pitch is judiciously chosen: this selection makes it possible to confer on the OBJECT OF THE INVENTION For a given correction power and a diameter of the patch, elimination of the distortions as previously described and in particular a maintenance of the initial power of the chip during its application to an optical component. In addition, this specific distribution of the Fresnel zones within the pellet makes it possible to minimize diffraction in a central zone of the object and to minimize diffusion in a non-central zone of the pellet, the latter being able to be induced in particular by makes of the limitation of the resolution of the tools and devices making it possible to realize such structures.

For this, the invention proposes a pellet of the type described above having a series of Fresnel zones on its concave spherical face, the pellet being intended to be fixed on a concave curved surface of an optical component to modify the power of this one. By modifying means either the contribution of an optical power to an optical component not comprising power, or a variation of the optical power to an optical component already comprising its own optical power. Thus according to the invention, the pellet has a generally spherical shape in addition to jumps in height that are present between the Fresnel zones, said Fresnel zones being present on the concave face of said chip, and the face of the chip coming into contact with the optical component being constituted by the smooth convex face of said chip. In other words, the smooth convex face of the pellet has an initial curvature which corresponds substantially to the shape of the concave curved surface of the optical component intended to receive said pellet. According to a particular embodiment of the invention this smooth convex face of the pellet may have a cylindrical surface or a toric surface. In such an embodiment, the tablet according to the invention makes it possible to take into account a correction of the astigmatism of a speaker. Indeed an astigmatic surface is characterized by the fact that the two main meridians do not have the same radius of curvature.

The concave face of the pellet which comprises the jumps in height also has a mean curvature which also corresponds to said curved surface of the optical component, this face being intended to be in contact with the ambient environment. Thus the overall profile of the Fresnel structure on the whole of the pellet has a spherical geometry.

For the purposes of the invention, the term "optical component" means visors such as helmet visors and ophthalmic lenses; ophthalmic lenses means lenses that are suitable in particular for a spectacle frame or a mask such as a ski mask, a sun mask or a diving mask, as well as masks whose function is to protect the eye and / or to correct the view, these lenses being chosen from afocal, unifocal, bifocal or progressive addition lenses. By mask, such as solar masks, is meant a lens consisting of a single piece and intended to be positioned in front of both eyes. Such ophthalmic lenses or visors may be optionally tinted. These optical components within the meaning of the invention may optionally have one or more functions that do not provide the application of one or more coatings and may especially be chosen from photochromic, anti-reflective, anti-fouling, anti-shock and anti-scratch coatings. , polarizing and antistatic. The invention is particularly suitable for corrective or non-corrective ophthalmic lenses. The curved power modification chip according to the invention consists of a material able to provide it with a cohesion with the optical component to which it must be bonded, this cohesion being either natural and due to the intrinsic properties of the sticky material (also called " tack "or" tackiness "in English), or initiated through the deposition of a thin layer of water, which serves as a vector for initiating and facilitating the bringing into contact between the pellet and the optical component.

The present invention thus comprises a wafer intended to be fixed on a curved concave surface of an optical component for modifying an optical power of said component, the wafer comprising a Fresnel lens formed of a series of Fresnel zones arranged at the same time. the interior of the others parallel to a smooth face of said wafer and having jumps in height between two successive zones, said height jumps being measured in a direction (z) perpendicular to the smooth face at an optical center of the wafer (O) , the tablet being characterized in that it has: a general spherical shape in addition to jumps in height between successive Fresnel zones, said generally spherical shape having an average radius of curvature of between 135 mm and 53 mm, and in which the jumps in height between successive Fresnel zones are located on a concave face of the patch, said jumps in height between zones of successive Fresnel presenting:

constant amplitudes inside a circle of radius (C) surrounding the optical center of the pellet (O) and of size defined as a function of the power of the pellet,

and variable amplitudes which increase in a peripheral part of the patch, away from the optical center (O) outside said circle (C),

said circle of radius (C) having a value of between 5 mm and 25 mm for a power comprised between 1 diopter and 10 diopters, and a first central amplitude of jump of height greater than or equal to 5 μm. According to a preferred embodiment of the invention, the pellet has a generally spherical shape comprising an average radius of curvature of between 88 mm and 53 mm, and very preferably substantially equal to 66 mm.

This average radius of curvature of 66 mm corresponds to a basic ophthalmic lens 8, this base being preferably implemented for the production of ophthalmic lenses of solar type, that is to say comprising a filter function. These ophthalmic lenses of solar type conventionally have a visible transmission rate of 88% and 6%. Such ophthalmic lenses meet the category 1 to 4 filter criteria according to the international classification used to classify sunscreens.

According to the invention, the jumps in height between successive Fresnel zones have constant amplitudes within an area surrounding the optical center of the patch. The concave face of the pellet which comprises the jumps in height then has a constant height of reliefs in a central part of this face. This helps to specifically limit the diffraction in the center of the pellet. On the other hand, according to a second characteristic, the jumps in height between successive Fresnel zones outside this central zone surrounding the optical center mentioned above have variable amplitudes up to the outer edge of said patch, this type of specific profile. to limit the diffusion in this area of the power pellet. The adjustment of the dimensioning of the constant amplitude in a central zone and of the variable amplitude in an area external to this central zone is chosen according to the power and the diameter of the power modification patch, these two parameters being themselves adjusted according to the personal visual correction of a wearer and his choice of the optical component on which he wishes to adapt the object of the present invention.

The invention also relates to an optical element which comprises a basic optical component and a patch as described above, fixed on the concave rear face of the component by means of its smooth convex face. As previously described, the basic optical component may be an ophthalmic lens. Preferably, such an ophthalmic lens is tinted or partially reflective and optionally has optical properties capable of correcting an ametropia. The pellet is then little visible and does not reduce the aesthetics of a pair of glasses that includes the lens, when applied to the concave or posterior face of the lens. The specific distribution profile of the constant and variable amplitudes of the Fresnel zones in the pellet according to the invention thus makes it possible to greatly improve the aesthetics of the device, particularly by minimizing the physical effects of diffraction and scattering of light rays. These are indeed not only troublesome for comfort and optical quality provides the wearer, but also disturbing for an observer placed in front of the wearer.

The invention also relates to a pair of spectacles which comprises at least one lens and a patch as described above, which is fixed on the lens. Such a pair of spectacles may be of the type of ametropia corrective glasses, tinted or not, or glasses or non-corrective sun protection mask, in particular.

Other features and advantages of the present invention will become apparent in the following description of nonlimiting exemplary embodiments, with reference to the appended drawings, in which:

- Figure 1a is a perspective view of a pellet according to the invention;

- Figure 1b is a sectional view of a pellet according to the invention;

- Figure 2a is a sectional view of an ophthalmic lens, adapted to be adapted to a pair of glasses, provided with pellets according to Figure 1b;

FIG. 3 is a diagram illustrating variations in height jumps for a tablet according to the invention;

For the sake of clarity, the dimensions of the elements shown are not in proportion to dimensions or dimensional ratios real. In addition, identical references in different figures designate identical elements.

According to Figures 1a and 1b, a tablet 1 according to the invention has a generally spherical shape, or cup. Preferably, the pellet has a spherical cap shape, with an average radius of curvature which may be of the order of 66 mm (millimeters) for example. Such a radius of curvature corresponds to the shape of the posterior face, or concave face, of many ophthalmic spectacle lenses. In the context of the invention, the pellets have an average radius of curvature of between 135 mm and 53 mm, advantageously between 88 mm and 53 mm.

The pellet 1 constitutes a Fresnel lens: it is formed of a succession of Fresnel zones which are concentrically arranged contiguously, for example 100 to 200 zones. These zones, referenced 2 in the figures are coaxial crowns which are oriented and centered along an optical axis marked z. The z axis then passes through an optical center of the pellet, which is located thereon and is denoted by O. In known manner, each Fresnel zone corresponds to a lens portion, and the thickness of the pellet 1 varies. continuously within this zone in a radial direction, denoted r, in a plane perpendicular to the z axis. Between two successive zones 2, one of the surfaces of the pellet 1 has a height jump parallel to the z axis, referenced 3. Its amplitude is noted Δz. It is specified that the jumps in height 3 that are present between successive zones 2 are superimposed on the general shape of the pellet 1, this general shape being curved, according to the invention. The jumps of height 3 correspond to discontinuities in height of the concave face of the pellet 1, referenced S1, the latter being intended to remain in contact with the surrounding medium. Between two successive jumps of height 3, a Fresnel zone 2 has a radial dimension which is denoted Δr, measured perpendicular to the z axis. The convex face of the pellet 1, referenced S2, is then smooth and is intended to be brought into contact with an optical component in order to constitute an optical element according to the invention, e denotes the average thickness of the pellet 1, between the faces S1 and S2. It is measured perpendicular to the S2 face. Preferably, the average thickness e is between 2 mm (millimeters) and 0.5 mm. This small thickness of the pellet limits the thickness of the optical element, and thus maintain the aesthetics of the object. In addition, the amount of material added to the optical component being low, this makes it possible to limit the total weight of the optical element.

In order to minimize the light scattering, and the diffraction and to cause no iridescence, or that these phenomena are not perceptible, the Fresnel zones 2 are dimensioned so that the amplitudes Δz of the jumps of height 3 are at least equal to five. times an average wavelength of visible light. Moreover, these Fresnel zones are distributed according to constant and variable amplitudes Δz as a function of their positioning with respect to the optical center (O) of the pellet. In a global manner, the amplitudes of jumps in height 3 are between 5 μm (micrometers) and 250 μm. In this way, because of the short coherence length of natural light, no interference that would occur between portions of a light beam passing through different areas 2 is perceptible. In other words, the pellet 1 has a purely refractive optical effect, which is related to the shape of the surfaces S1 and S2 in each zone 2, and produces no visible diffractive effect. As previously described, the amplitudes of the jumps of height 3 between successive Fresnel zones are constant over a central portion (C) and variable over a portion of the surface of the chip extending outside the circle (C) to a peripheral part, while maintaining a substantially spherical profile on the surface (S1). In this configuration, the amplitude Δz is greater at the periphery of the pellet than in its central zone. Thus according to the invention, the pellet is such that the jumps in height (3) between successive Fresnel zones inside the circle (C) have amplitudes of between 5 μm and 25 μm, and the jumps in height (3). ) between successive Fresnel zones at the outside of the circle (C) to a peripheral portion of the pellet have variable amplitudes of between 5 μm and 250 μm.

Advantageously, the patch is such that the jumps in height (3) between successive Fresnel zones inside the circle (C) have amplitudes of between 10 μm and 20 μm,

According to a particular embodiment of the invention, the pellet may have in its outer peripheral peripheral edge a third peripheral zone defines (A) in Figure 1b, including jumps of constant heights. This peripheral zone is sometimes called a non-useful zone. Indeed it is known to those skilled in the art that the optically useful area covers the entire lens which has a limited diameter. However in some cases, a peripheral zone is provided on the periphery of the ophthalmic lens. This zone is said peripheral because it does not meet the conditions of optical correction prescribed and has defects of obliquities. The defects of this peripheral zone do not affect the visual comfort of the wearer because this area is outside the field of view of the wearer. This so-called peripheral zone (A) can therefore be provided within the power-modifying chip and for reasons of embodiment and / or aesthetics it may be advantageous for the latter to present constant-amplitude fresnel zones. Thus according to this embodiment, the pellet is such that the jumps in height (3) between successive Fresnel zones in the peripheral zone (A) have constant amplitudes said amplitude corresponding to the amplitude of the last jump of height (3) between successive Fresnel zones outside the circle (C), and a constant dimension (Δr) corresponding to the constant dimension (Δr) between successive Fresnel zones outside the circle (C)

The radial dimension Δr of each zone 2 then depends on the optical power of the pellet 1 and the amplitude Δz of the height jumps 3.

Under the above conditions, and for an optical power of the pellet 1 less than or equal to 10 diopters, Δr can be between 100 microns and 5 mm. According to the invention, the pellet is such that the Fresnel zones (2) have a dimension (Δr) variable between 5 mm and 100 μm inside the circle (C), the largest dimension being closer to the center (O) of the circle (C), and the Fresnel zones (2) have a constant dimension (Δr) of between 500 μm and 100 μm outside the circle (C). In a preferential manner, the pellet according to the invention is such that the Fresnel zones (2) have a variable size (Δr) of between 2.5 mm and 250 μm inside the circle (C), the most large dimension is closest to the center (O) of the circle (C), and the Fresnel zones (2) have a constant dimension (Δr) of 250 μm outside the circle (C). The pellet 1 may have a positive or negative vergence, depending on the direction of variation of its thickness along the direction r, within each Fresnel zone 2. FIG. 1b corresponds to a convergent pellet. The variation of the thickness of the pellet inside each zone 2 may be, in particular, a quadratic function of r. The tablet according to the invention may also have a cylinder, which then makes it possible to take into account the astigmatism of the wearer if necessary. In this particular embodiment, the pellet is such that the smooth convex front face of said pellet has a cylindrical surface or a toric surface.

FIG. 2a shows an ophthalmic lens adaptable to a pair of spectacles which are provided, on their posterior faces SO, or concave faces, with pellets according to FIG. 1b. The lens of FIG. 2a, referenced 10, may be a sun protection lens with zero optical power, since it has two parallel faces. The pellet 1 then gives it a non-zero power, which corrects a lack of ametropia and possibly astigmatism of a wearer of the lens. In this way, the patch 1 makes it possible to adapt any sun protection lens to a wearer having a visual distortion. The pair of spectacles comprising such a lens 10 may then be chosen by the wearer according to his aesthetics, his color, or the shape of the associated frame. The lens of Figure 2a, referenced 10, corresponds to a correction of myopia, since it is thinner at its center than at its periphery. The pellet 1 then allows to adapt the strength of the correction according to the degree of myopia of the wearer. In this case, the tablet 1 is placed on the glass 10 so as to superpose the respective optical axes of the glass and the tablet. An identical function is obtained with a corrective lens of hyperopia. The pellet 1 is applied to the posterior surface SO of the lens 10 which is smooth. This operation can be done directly by the practitioner or the wearer on the pair of glasses in which the lens is mounted on the frame chosen by the wearer.

FIG. 3 represents an example of variation of the amplitudes Δz of the jumps of height 3 along the radial direction r. When r is smaller than radius

Rc of the circle C, the amplitudes Δz of the jumps 3 are constant and the radial dimension Δr of the zones 2 decreases for zones 2 of larger and larger. Beyond the value Rc, that is to say in a peripheral portion of the pellet 1 outside the circle C, the jumps of height 3 have amplitudes Δz which increase.

The pellet 1 is adhered to the face SO of the lens 10, thanks to the intrinsic adhesion properties of the material constituting said pellet, or possibly by using a thin film of water between the two interfaces, which serves as vector to initiate contact between elements. Thus, according to the invention, the material constituting the pellet must combine both transparency properties that make it possible to preserve the optical quality of the optical component intended to receive it, the "tack" properties, as well as the physical properties enabling it to be conferred. a certain flexibility in order to adapt it in a manner to the radius of curvature of the optical component to wear it. Advantageously, the material constituting the pellet according to the invention has a hardness of between 70 and 95 shore A, a diffusion of between 2.0% and 0.4%, preferably less than 1%. Among the materials that can be used within the scope of the invention, mention will in particular be made of transparent thermoplastic materials chosen from polyurethane polymers, polyvinyl chloride, polyethylene terephthalate polymers, poly (meth) acrylate polymers and polycarbonate polymers. In a preferential way the constituent material of the pellet is selected from thermoplastic polyurethane and thermoplastic polyvinyl chloride.

The material of the ophthalmic lens can be of mineral or organic type. As an indication but not limiting, mention may be made as organic material that can be used in the context of the invention the materials conventionally used in optics and ophthalmia. For example, substrates of the polycarbonate type are suitable; polyamide; polyimides; polysulfones; copolymers of poly (ethylene terephthalate) and polycarbonate; polyolefins, especially polynorbornenes; polymers and copolymers of diethylene glycol bis (allyl carbonate); (meth) acrylic polymers and copolymers, especially polymers and (meth) acrylic copolymers derived from bisphenol-A; thio (meth) acrylic polymers and copolymers; urethane and thiourethane polymers and copolymers; epoxy polymers and copolymers and episulfide polymers and copolymers. It is understood that many adaptations can be introduced in the embodiments which have been described in detail above, while retaining at least some of the advantages of the invention. In particular, those skilled in the art will understand that the materials and values cited are for illustrative purposes only, and may be modified.

Claims

1. Pad (1) intended to be fixed on a concave curved surface

(SO) of an optical component (10) for modifying an optical power of said component, the chip comprising a Fresnel lens formed of a series of Fresnel zones (2) arranged inside each other parallel to a smooth face of said pellet (S2) and having jumps in height (3) between two successive zones, said height jumps being measured in a direction (z) perpendicular to the smooth face at an optical center of the pellet (O), the tablet being characterized in that it has: a general spherical shape in addition to jumps in height (3) between successive Fresnel zones, said general spherical shape having an average radius of curvature of between 135 mm and 53 mm,

- And in which the jumps in height (3) between successive Fresnel zones are located on a concave face (S1) of the pellet, said jumps in height (3) between successive Fresnel zones having:

constant amplitudes inside a circle of radius (C) surrounding the optical center of the pellet (O) and of size defined as a function of the power of the pellet,

and variable amplitudes which increase in a peripheral part of the patch, away from the optical center (O) outside said circle (C),

said circle of radius (C) having a value of between 5 mm and 25 mm for a power comprised between 1 diopter and 10 diopters, and a first central amplitude of jump of height greater than or equal to 5 μm.

2. The tablet of claim 1 having an average radius of curvature of between 88 mm and 53 mm, and preferably equal to 66 mm.

3. The tablet according to any one of claims 1 or 2, wherein the jumps in height (3) between successive Fresnel zones to inside the circle (C) have amplitudes between 5 μm and 25 μm, and the jumps in height (3) between successive Fresnel zones outside the circle (C) to a peripheral portion of the pellet have variable amplitudes between 5 μm and 250 μm.

The tablet according to claim 3, wherein the height jumps

(3) between successive Fresnel zones inside the circle (C) have amplitudes of between 10 μm and 20 μm,

5. A tablet according to any one of the preceding claims, wherein the Fresnel zones (2) have a dimension (Δr) of between 100 μm and 5 mm, in a radial direction (r) passing through the optical center (O). and perpendicular to an optical axis of the pellet.

6. A tablet according to claim 5 wherein the Fresnel zones (2) have a dimension (Δr) variable between 5 mm and 100 microns inside the circle (C) the largest dimension is closest to the center (O) of the circle (C), and the Fresnel zones (2) have a constant dimension (Δr) of between 500 μm and 100 μm outside the circle (C).

7. A tablet according to claim 6 wherein the Fresnel zones (2) have a variable size (Δr) of between 2.5 mm and 250 μm inside the circle (C), the largest dimension being at most near the center (O) of the circle (C), and the Fresnel zones (2) have a constant dimension (Δr) of 250 μm outside the circle (C).

8. A tablet according to any one of the preceding claims, wherein the jumps in height (3) between successive Fresnel zones in the peripheral zone (A) have constant amplitudes said amplitude corresponding to the amplitude of the last jump of height ( 3) between successive Fresnel zones outside the circle (C), and a constant dimension (Δr) corresponding to the constant dimension (Δr) between successive Fresnel zones outside the circle (C)

9. A tablet according to any one of the preceding claims, having an average thickness (e) of between 2 mm and 0.5 mm, measured perpendicularly to the smooth face (S2) of the pellet.

10. A tablet according to any one of the preceding claims wherein the smooth convex front face of said wafer has a cylindrical surface or a toric surface.

11. A tablet according to any one of the preceding claims, comprising a transparent material having a hardness between 70 and 95 Shore A.

12. A tablet according to any one of the preceding claims, comprising a transparent material having a diffusion of between 2.0% and 0.4%, preferably less than 1%.

13. A tablet according to any one of claims 11 and 12, comprising a transparent thermoplastic material selected from polyurethane polymers, polyvinyl chloride, polyethylene terephthalate, polymethyl (meth) acrylate and polycarbonate.

14. A tablet according to claim 13 comprising a transparent material chosen from thermoplastic polyurethane and thermoplastic polyvinyl chloride.

An optical element comprising a base optical component (10) and a wafer (1) according to any one of claims 1 to 14, said wafer being fixed on the concave rear face of said component by means of its smooth convex face.

The element of claim 15, wherein the wafer (1) is attached to the component (10) by means of a film of water disposed as a carrier between said wafer and said component.

An element according to any one of claims 15 or 16, wherein the base component is an ophthalmic lens.

The element of claim 17, wherein the base component is an ophthalmic corrective ametropic lens.

The element of claim 17 or 18, wherein the ophthalmic lens is tinted or partially reflective.

20. Element according to any one of claims 15 to 19, wherein the base component is a lens adapted to a pair of sunglasses (10).

21. Element according to any one of claims 15 to 19, wherein the base component is a mask lens, including sun mask, ski or diving, or a visor, including a helmet visor.

22. Pair of spectacles comprising at least one lens (10) and a wafer (1) according to any one of claims 1 to 14, fixed on said lens.